Slave boson

The slave boson method is a technique for dealing with models of strongly correlated systems, providing a method to second-quantize valence fluctuations within a restrictive manifold of states. In the 1960s the physicist John Hubbard introduced an operator, now named the "Hubbard operator"^[1] to describe the creation of an electron within a restrictive manifold of valence configurations. Consider for example, a rare earth or actinide ion in which strong Coulomb interactions restrict the charge fluctuations to two valence states, such as the Ce⁴⁺(4f⁰) and Ce³⁺ (4f¹) configurations of a mixed-valence cerium compound. The corresponding quantum states of these two states are the singlet ${\displaystyle \vert f^{0}\rangle }$ state and the magnetic ${\displaystyle \vert f^{1}:\sigma \rangle }$ state, where ${\displaystyle \sigma =\uparrow ,\ \downarrow }$ is the spin. The fermionic Hubbard operators that link these states are then

${\displaystyle X_{\sigma 0}=\vert f^{1}:\sigma \rangle \langle f^{0}\vert ,\qquad X_{0\sigma }=\vert f^{0}\rangle \langle f^{1}:\sigma \vert }$

(1)

The algebra of operators is closed by introducing the two bosonic operators

${\displaystyle X_{00}=\vert f^{0}\rangle \langle f^{0}\vert ,\qquad X_{\alpha \beta }=\vert f^{1}:\alpha \rangle \langle f^{1}:\beta \vert }$.

(2)

Together, these operators satisfy the graded Lie algebra

${\displaystyle [X_{ab},X_{cd}]_{\pm }=X_{ad}\delta _{bc}\pm X_{cb}\delta _{ad}}$

(3)

where the ${\displaystyle [A,B]_{\pm }=AB\pm BA}$ and the sign is chosen to be negative, unless both ${\displaystyle A}$ and ${\displaystyle B}$ are fermions, in which case it is positive. The Hubbard operators are the generators of the super group SU(2|1). This non-canonical algebra means that these operators do not satisfy a Wick's theorem, which prevents a conventional diagrammatic or field theoretic treatment.

In 1983 Piers Coleman introduced the slave boson formulation of the Hubbard operators,^[2] which enabled valence fluctuations to be treated within a field-theoretic approach.^[3] In this approach, the spinless configuration of the ion is represented by a spinless "slave boson" ${\displaystyle \vert f^{0}\rangle =b^{\dagger }\vert 0\rangle }$, whereas the magnetic configuration ${\displaystyle \vert f^{1}:\sigma \rangle =f_{\sigma }^{\dagger }\vert 0\rangle }$ is represented by an Abrikosov slave fermion. From these considerations, it is seen that the Hubbard operators can be written as

${\displaystyle X_{\sigma 0}=f_{\sigma }^{\dagger }b,\qquad X_{0\sigma }=b^{\dagger }f_{\sigma }}$

(4)

and

${\displaystyle X_{00}=b^{\dagger }b,\qquad X_{\alpha \beta }=f_{\alpha }^{\dagger }f_{\beta }}$.

(5)

This factorization of the Hubbard operators faithfully preserves the graded Lie algebra. Moreover, the Hubbard operators so written commute with the conserved quantity

${\displaystyle Q=b^{\dagger }b+\sum _{\alpha =\uparrow ,\downarrow }f_{\alpha }^{\dagger }f_{\alpha }}$.

(5)

In Hubbard's original approach, ${\displaystyle Q=1}$, but by generalizing this quantity to larger values, higher irreducible representations of SU(2|1) are generated. The slave boson representation can be extended from two component to ${\displaystyle N}$ component fermions, where the spin index ${\displaystyle \alpha \in [1,N]}$ runs over ${\displaystyle N}$ values. By allowing ${\displaystyle N}$ to become large, while maintaining the ratio ${\displaystyle Q/N}$, it is possible to develop a controlled large-${\displaystyle N}$ expansion.

The slave boson approach has since been widely applied to strongly correlated electron systems, and has proven useful in developing the resonating valence bond theory (RVB) of high temperature superconductivity^[4][5] and the understanding of heavy fermion compounds.^[6]

Bibliography

1. Hubbard, John (1964). "Electron correlations in narrow energy bands. II. The degenerate band case". Proc. R. Soc. Lond. A. 277 (1369). The Royal Society: 237–259. Bibcode:1964RSPSA.277..237H. doi:10.1098/rspa.1964.0019. S2CID 122573530.
2. Piers Coleman (1984). "A New Approach to the Mixed Valence Problem". Phys. Rev. B. 29 (6). The American Physical Society: 3035–3044. Bibcode:1984PhRvB..29.3035C. doi:10.1103/PhysRevB.29.3035.
3. N. Read and D. M. Newns (1983). "A new functional integral formalism for the degenerate Anderson model". Journal of Physics C: Solid State Physics. 16 (29): L1055–L1060. doi:10.1088/0022-3719/16/29/007.
4. P. W. Anderson; G. Baskaran; Z. Zhou; T. Hsu (1987). "Resonating–valence-bond theory of phase transitions and superconductivity in La2CuO4-based compounds". Physical Review Letters. 58 (26). The American Physical Society: 2790–2793. Bibcode:1987PhRvL..58.2790A. doi:10.1103/PhysRevLett.58.2790. PMID 10034850.
5. G. Kotliar and J. Liu (1988). "Superexchange mechanism and d-wave superconductivity". Physical Review B. 38 (7). The American Physical Society: 5142–5145. Bibcode:1988PhRvB..38.5142K. doi:10.1103/PhysRevB.38.5142. PMID 9946940.
6. A. J. Millis; P.A. Lee (1986). "Large-orbital-degeneracy expansion for the lattice Anderson model". Physical Review B. 35 (7). The American Physical Society: 3394–3414. doi:10.1103/PhysRevB.35.3394. PMID 9941843.

• Coleman, Piers (15 March 1984). "New approach to the mixed-valence problem". Physical Review B. 29 (6). American Physical Society (APS): 3035–3044. Bibcode:1984PhRvB..29.3035C. doi:10.1103/physrevb.29.3035. ISSN 0163-1829.